A kick scooter steering control mechanism includes a five-bar linkage formed of a bracket, two toggle members and two follower levers to achieve a three-dimensional linking effect for enabling the front wheels of the kick scooter to be turned smoothly to change the steering direction.

Patent
   6382646
Priority
Jan 24 2001
Filed
Jan 24 2001
Issued
May 07 2002
Expiry
Jan 24 2021
Assg.orig
Entity
Small
36
22
EXPIRED
1. A kick scooter steering control mechanism installed in the footplate of a kick scooter having two front wheels and adapted to control the steering of the kick scooter, comprising:
a bracket fixedly provided at the front side of the footplate of said kick scooter, said bracket comprising a top beam and a bottom beam;
two toggle members respectively fastened to the front wheels of said kick scooter and pivoted to said bracket and disposed at two sides between said top beam and said bottom beam, said toggle members each comprising an arm, which is moved horizontally when the front wheels are turned through an angle;
spring members respectively coupled between said toggle members and said top beam of said bracket to impart a downward pressure to said toggle members;
two follower levers respectively coupled between the arms of said toggle members and the footplate of said kick scooter and movable vertically upon horizontal movement of the arms of said toggle members, said follower levers each having a first end coupled to the footplate of said kick scooter and a second end coupled to the arm of one of said toggle members.
2. The kick scooter steering control mechanism of claim 1, wherein the footplate of said kick scooter comprises two spherical connectors disposed at a front side thereof, and said follower levers each have a ball socket provided at the respective first end and coupled to one spherical connector of the footplate of said kick scooter.
3. The kick scooter steering control mechanism of claim 1, wherein the arms of each of said toggle member comprises a spherical connector disposed at one end, and said follower levers each have a ball socket provided at the respective second end and coupled to the spherical connector of the arm of one of said toggle members.
4. The kick scooter steering control mechanism of claim 1 further comprising two guide rods respectively inserted through said toggle members and said spring members and bilaterally connected between said top beam and said bottom beam.
5. The kick scooter steering control mechanism of claim 4, wherein said guide rods have a non-circular cross section and are respectively mounted with a respective axle cap respectively supported between said spring members and said toggle members, said axle cap having a non-circular axial hole fitting the non-circular cross section of the respective guide rod and an uneven bottom edge; said toggle members each have at least one raised portion respectively fitting the uneven bottom edge of the axle cap on each of said guide rods.
6. The kick scooter steering control mechanism of claim 1, wherein said spring members are compression springs.

The present invention relates to kick scooters and, more specifically, to a steering control mechanism for kick scooter.

FIGS. 1 and 2 show a handlebar-controlled kick scooter according to the prior art. This structure of kick scooter comprises a footplate 1, a bracket 2 fixedly provided at the front side of the footplate 1, a rear wheel 3 pivoted to the rear side of the footplate 1, and a steering control column 4 fixedly provided at the top side of the bracket 2, two actuating members 5 bilaterally pivoted to the bottom side of the bracket 2 and respectively fixedly connected to the wheel axles of the front wheels 6, a link coupled between the actuating members 5, a spacer 7 mounted on the link, and two spring members 8 respectively mounted on the link and stopped between two opposite sides of the spacer 7 and the actuating members 5. When changing the steering direction of the front wheels 6, the actuating members 5 are turned in one direction to compress one spring member 8 and stretch the other spring member 8. The spring members 8 prevent an overturn, and automatically force the front wheels 6 back to the center position after the turning force has been released from the front wheels 6. The bracket 2, the actuating members 5 and the link form a four-bar linkage to achieve a two-dimensional swinging movement about the pivoted point between each actuating member 5 and the bracket 2. According to this structure of kick scooter, the front wheels 6 receive a component of force in the turning direction and a downward pressure from the rider through the bracket 2 and the actuating members 5, and the downward pressure interferes with the transmission of the turning force to the front wheels 6. In order to overcome the downward pressure when changing the steering direction of the front wheels 6, the rider must employ much effort to the front wheels 6.

The present invention has been accomplished to provide steering control mechanism for kick scooter, which eliminates the aforesaid problem. It is the main object of the present invention to provide a kick scooter steering control mechanism, which enables the rider to control the steering of the kick scooter smoothly with less effort. It is another object of the present invention to provide a kick scooter steering control mechanism, which provides a five-bar linkage to achieve a three-dimensional linking effect for enabling the front wheels of the kick scooter to be turned with less effort to change the steering direction of the kick scooter smoothly. According to the present invention, the kick scooter steering control mechanism is installed in the footplate of a kick scooter having two front wheels and adapted to control the steering of the kick scooter, comprising: a bracket fixedly provided at the front side of the footplate of the kick scooter, the bracket comprising a top beam and a bottom beam; two toggle members respectively fastened to the front wheels of the kick scooter and pivoted to the bracket and disposed at two sides between the top beam and the bottom beam, the toggle members each comprising an arm, which is moved horizontally when the front wheels are turned through an angle; a spring members respectively coupled between the toggle members and the top beam of the bracket to impart a downward pressure to the toggle members; two follower levers respectively coupled between the arms of the toggle members and the footplate of the kick scooter and turned vertically upon horizontal movement of the arms of the toggle members, the follower levers each having a first end coupled to the footplate of the kick scooter and a second end coupled to the arm of one of the toggle members.

FIG. 1 is an elevational view of a kick scooter according to the prior art.

FIG. 2 is a bottom view of the kick scooter shown in FIG. 1.

FIG. 3 is a front view and partially in section of the kick scooter steering control mechanism according to the present invention.

FIG. 4 is a top view of the kick scooter steering control mechanism according to the present invention.

FIG. 5 is a top view, partially in section, of the kick scooter steering control mechanism according to the present invention.

FIG. 6 is a bottom view of the kick scooter steering control mechanism according to the present invention.

FIG. 7 is a front view of the present invention, showing the steering direction of the front wheels changed.

FIG. 8 is a top view, partially in section of FIG. 7.

Referring to FIGS. From 3 through 6, a kick scooter steering control mechanism in accordance with the present invention is shown provided at the front side of the kick scooter's footplate 100 for steering control. The footplate 100 comprises two spherical connectors 101 at its front side. The steering control mechanism is comprised of a bracket 10, two guide rods 20, two toggle members 30, two axle caps 40, two spring members 50, and two follower levers 60.

The bracket 10 is a substantially I-shaped frame comprising a top beam 11 and a bottom beam 12. The middle part of the bracket 10 is fixedly fastened to the front side of the footplate 100 by a fastening element, for example, a screw bolt 13. The top beam 11 and the bottom beam 12 each have two through holes 111 or 121 at two ends. The guide rods 20 are respectively fixedly connected between the through holes 111 of the top beam 11 and the through holes 121 of the bottom beam 12, each having an upper part of polygonal cross section 21 and a lower part of circular cross section 22. The toggle members 30 each comprise a circular axial hole 31 coupled to the lower part 22 of one guide rod 20, a first arm 32 and a second arm 33 arranged at right angles, and two protruded portions 35 and 36 disposed at the top sidewall thereof. The first arm 32 of each toggle member 30 is respectively fixedly connected to the wheel axle of each front wheel 200. The second arm 33 of each toggle member 30 has one end terminating in a spherical connector 34. When turning the front wheels 200, the second arms 33 are moved horizontally. The axle caps 40 each comprise an axial hole 41 of polygonal cross section fitting and coupled to the polygonal upper part 21 of one guide rod 20, and an uneven bottom edge fitting over the raised portions 35 and 36 of the top sidewall of one toggle member 30. When the toggle members 30 are turned with the front wheels 200, the raised portions 35 and 36 of the toggle members 30 push the axle caps 40 upwards. Because the polygonal axial hole 41 of each axle cap 40 is respectively coupled to the polygonal upper part 21 of each guide rod 20, the axle caps 40 are prohibited from a rotary motion relative to the guide rods 20 and forced to move upwards along the guide rods 20 when receive pressure from the raised portions 35 and 36 of the toggle members 30. The spring members 50 are, for example, compression springs respectively sleeved onto the upper part of polygonal cross section 21 of each guide rod 20 and stopped between the top beam 11 and the axle caps 40. When the axle caps 40 are moved upwards, the compression springs 50 are compressed. When the axle caps 40 are released from the pressure of the toggle members 30 (the front wheels 200), the compression springs 50 immediately push the axle caps 40 downwards to force the toggle members 30 back to their former position, thereby causing the front wheels 200 to be returned to the center position. The two follower levers 60 each comprises a first ball socket 61 horizontally facing the footplate 100 and coupled to one spherical connector 101 of the footplate 100, a second ball socket 62 facing vertically downwards and coupled to the spherical connector 34 of one toggle member 30, and two jackets 63 respectively covered on ball sockets 62 to secure the ball sockets 62 to the respective spherical connectors 101 and 34.

The function and advantages of the present invention will become apparent from the following description. When the front wheels 200 are kept in the center positions, as shown in FIGS. 3 and 5, the second ball sockets 62 of the follower levers 60 are disposed at a higher elevation than the first ball sockets 61, the axle caps 40 are maintained in close contact with the toggle members 30, and the compression springs 50 receive no pressure. When the front wheels 200 are turned in one direction as shown in FIGS. 7 and 8, the toggle members 30 are moved with the front wheels, and the second arms 33 are turned with the toggle members 30 horizontally through an angle to force the follower levers 60 to turn vertically, and at the same time the raised portions 35 and 36 are moved with the toggle members 30 to push the axle caps 40 upwards along the respective guide rods 20 to compress the compression springs 50. When the turning force is released from the front wheels 200, the compression springs 50 immediately push the toggle members 30 to force the front wheels 200 back to the center position.

As indicated above, the bracket 10, the toggle members 30 and the follower levers 60 form a five-bar linkage, achieving a three-dimensional linking effect and preventing obstruction between parts. Therefore, the front wheels 200 can easily turned with less effort to change the steering direction of the kick scooter.

While only one embodiment of the present invention has been shown and described, it will be understood that various modifications and changes could be made thereunto without departing from the spirit and scope of the invention disclosed.

Shaw, Athony

Patent Priority Assignee Title
10322767, Jan 24 2016 Carry-on foldable stepper scooter
10376773, Jan 29 2004 RC INNOVATION, LLC Wheel-bearing truck
10384116, Nov 06 2018 Steering apparatus of a skateboard
10450027, Jul 20 2016 COOLRYDE B V Golf-bag carrying vehicle
10494050, Dec 01 2014 Radio Flyer INC Steering mechanism for scooter
10501119, Nov 15 2017 Sway Motorsports LLC Control system for a tiltable vehicle
10617936, May 10 2016 SKATE INNOVATIONS PTY LTD Personal transport apparatus
10946922, Feb 16 2017 Mattel, Inc. Ride-on toy vehicle configured to tilt and drift
11052942, Feb 22 2019 Sway Motorsports LLC Three-wheeled tilting vehicle
11072389, Feb 22 2019 Sway Motorsports LLC Three-wheeled tilting vehicle
11420703, Apr 23 2018 Audi AG Scooter and method for operating a scooter
11439890, May 10 2017 SKATE INNOVATION PTY LTD. Personal transport apparatus
6520517, May 25 2001 RC INNOVATION, LLC Riding device
6938907, Jan 07 2002 TREBMOTION, LLC Lean-induced steerable wheel assembly
7044485, Sep 20 2003 Elastomeric suspension system skateboard truck
7150461, Jan 07 2002 MINSON ENTERPRISES CO , LTD ; Stowbiz, LLC Foldable skateboard
7243925, Aug 29 2002 System Boards Australia Pty Ltd Truck assemblies for skateboards
7665749, Apr 17 2007 SWAY MOTORSPORTS, INC Suspension assembly having an integrated stable storage platform
7722063, Oct 31 2005 DIEZIGER, DAVID Vehicle suspension system
7783392, Oct 13 2005 Toyota Jidosha Kabushiki Kaisha Traveling apparatus and method of controlling the same
8500138, Sep 17 2010 Surf-Rodz LLC Skateboard truck with replaceable hanger and hanger for skateboard truck
8608185, Jan 06 2012 REINCARNATE, INC Skateboard truck
8684376, Jan 09 2012 NATION EQUITY, LLC Three wheel lean-steer skateboard
8696000, Jan 14 2013 Scooter
8740236, Jan 17 2011 Micro Mobility Systems AG Infant scooter
8746716, Jan 09 2012 NATION EQUITY, LLC Three wheel lean-steer skateboard
8936251, Apr 25 2014 Skate system including active displacement mechanism
8985602, Aug 08 2012 NICER HOLDINGS LIMITED Scooter
9022406, Jan 17 2011 Micro Mobility Systems AG Infant scooter
9132338, Sep 08 2010 Deck wheeled device
9365256, Jan 17 2011 Micro Mobility Systems AG Infant scooter
9381968, Aug 08 2012 NICER HOLDINGS LIMITED Scooter
9701339, Jan 29 2014 Vehicle with tilting frame
D736861, Dec 01 2014 Radio Flyer INC Scooter
D749174, Nov 04 2014 Scooter
D756465, Mar 06 2015 Radio Flyer INC Scooter
Patent Priority Assignee Title
2032657,
2531933,
2791440,
4054297, Jun 18 1976 Ermico Enterprises Weight biased steering mechanism
4403784, Jan 22 1981 Roller skate axle suspension
4550926, Mar 28 1984 Vehicle suspension system
4775162, Jul 24 1987 CHAO, JUNG-HSIANG Swingable skateboard
4951958, Jul 24 1987 Swingable skateboard with two brake assemblies
5048632, Oct 26 1988 Self-propelled device
5263725, Feb 24 1992 GEBR OUBOTER GMBH Skateboard truck assembly
5330214, Sep 03 1991 Simplified steering mechanism for skateboards and the like
5762351, Jun 26 1995 Multi-track vehicle with lock and drive lean control system
5924710, Oct 30 1995 Sports conveyance suspension systems
5950754, Jul 22 1997 Multi-terrain riding board
5997018, May 09 1994 MOUNTAINBOARD SPORTS, INC F K A All terrain sport board and steering mechanisms for same
6170242, Jul 22 1997 Ferris Industries, Inc.; FERRIS INDUSTRIES INC Lawn mower having independent drive wheel suspension
6206388, May 14 1999 Scooter board
6224076, Mar 16 2000 Tracy Scott, Kent Pneumatic compression strut skateboard truck
6279930, Dec 27 1999 Structure of scooter
6286843, Sep 05 2000 Steering mechanism of handle-controlled skate board
6299186, Apr 28 2000 Antishock structure of scooter
D445145, Jan 09 2001 Scooter
Executed onAssignorAssigneeConveyanceFrameReelDoc
Date Maintenance Fee Events
Nov 23 2005REM: Maintenance Fee Reminder Mailed.
May 08 2006EXP: Patent Expired for Failure to Pay Maintenance Fees.


Date Maintenance Schedule
May 07 20054 years fee payment window open
Nov 07 20056 months grace period start (w surcharge)
May 07 2006patent expiry (for year 4)
May 07 20082 years to revive unintentionally abandoned end. (for year 4)
May 07 20098 years fee payment window open
Nov 07 20096 months grace period start (w surcharge)
May 07 2010patent expiry (for year 8)
May 07 20122 years to revive unintentionally abandoned end. (for year 8)
May 07 201312 years fee payment window open
Nov 07 20136 months grace period start (w surcharge)
May 07 2014patent expiry (for year 12)
May 07 20162 years to revive unintentionally abandoned end. (for year 12)